Method for providing the mesh of a silk screen at an angle for minimizing moire

ABSTRACT

Silk-screens of annular-shape are provided for the silk-screen printing of halftones on compact discs. The silk-screens are rotatably provided in a carrier so that the angle at which moire can be eliminated or at least minimized or localized for the printing of a particular color can be determined. Following the determination of that angle for each of the colors to be printed, the screens are each then provided with photosensitive emulsion, exposed to light, and washed. The silk-screens are then placed in another carrier at the same angle as before determined for the elimination or at least the minimization or localization of moire, this carrier being capable of being placed directly into the nest of a print head of a conventional silk-screen printing machine.

This application is a division of application Ser. No. 08/711,327, filedSep. 3, 1996, now U.S. Pat. No. 5,752,441, which is a division ofapplication Ser. No. 08/512,770, filed Aug. 9, 1995, now abandoned.

BACKGROUND OF THE INVENTION

(1). Field of the Invention

This invention relates, in general, to silk-screen printing. Moreparticularly, the invention relates to silk-screen members used in amulticolor half tone silk-screen printing process, such as thefour-color silk-screen printing of the surface of a compact disc, and tothe method of manufacture of those silk-screen members.

(2). Description of the Prior Art

Silk-screen printing, in general, involves the use of a screen, i.e., awoven mesh fabric, stretched over a frame and the design or text to beprinted is provided on the screen in outline form, in the nature of astencil. The design to be printed is provided in the silk-screen, ingeneral, by coating the screen with a photosensitive emulsion, exposingthe emulsion to obtain the desired image and then washing the unexposedareas to leave the screen with the image to be printed. The design ortext is reproduced on a desired object, e.g., the surface of a compactdisc, by having a squeegee force color, i.e., ink, through the mesh ofthe exposed areas of the screen. Thus, the image or text printedcomprises a plurality of closely spaced dots of color.

Half-tone printing, contrary to full color printing, involves a shadingor gradation of color, In such printing, the gradation of the tone ofcolor is obtained by a system of closely spaced dots arranged inparallel lines. For example, in the four color printing of the surfaceof a compact disc, this involves the separate printing, in turn, of aline of dots of cyan, black, magenta, and yellow of full color. Theselines of dots of different color must be printed at predeterminedangles, i.e., the angles of color separation, and in proper linearregistration with one another to provide the desired gradation of colorand to prevent moire. The angles of color separation depend to someextent upon the particular printing process involved, i.e., offset,silk-screen, etc. It is important that the three darkest colorsinvolved, i. e., magenta, black, and cyan be at angles 30° apart fromone another, i.e., 15°, 45°, and 750° respectively. The yellow colorseparation should desirably be at either 0° or 90°. An almost endlessnumber of color tints can be obtained by combining these four basiccolors. As is known by those skilled in the art of silk-screen printing,these angles of color separation follow the so-called "North American"standard. These angles, at which lines of dots of color should beprinted in halftone printing, do not necessarily, however, provide theideal solution for silk-screen printing. Many silk-screen printingoperators have developed their own color separation angles that workwith the mesh counts usually used in silk-screen printing processes.

Registration of the lines of printed dots to one another to provide asuitable halftone presents no particular problem in printing processesother than in silk-screen printing. In the case of silk-screen printing,the proper registration of the lines of dots of color being printed isof particular concern. Otherwise, "moire" occurs. Moire can result forseveral reasons, as is well known to those skilled in the art ofsilk-screen printing. Nevertheless, perhaps the major reason is the factthat the line of dots of one or more of the color separations may not beprovided at the desired angle. Thus, for example, in the first colorbeing printed, if the angle of the dots being printed is only slightlydifferent from the angle of color separation for that color, moire willoccur even though the other lines of dots of color are printed at thecorrect angles of color separations. Or, on the other hand, the firstcolor printed may be at the correct angle of color separation, and oneor more of the subsequent colors printed is printed at an improperangle.

Moire manifests itself in a series of vertical lines, i.e., lines ofdots of color, being in one direction, spaced apart from one another,and at an angle somewhat different from that desired. These linespresent an unsuitable shimmering pattern or wave-like appearance in thegradation of color on the object being printed. Moire is a particularproblem in the four-color silk-screen printing of objects, e.g., thesurface of a compact disc. In this case, each of the four halftonescreens used in the printing process must have the mesh in the screen atthe proper angle, to avoid the moire effect.

Heretofore, the manner of eliminating, or at least reducing, moire insilk-screen printing has been most difficult. Changing the angle or sizeof the screen, i.e., the mesh count of the woven fabric used in themanufacture of the screen, usually solves the problem. Nevertheless, themanufacture of a silk-screen for halftone printing is a somewhat costlyand labor intensive operation. Where moire occurs, the making of a newset of screens, e.g., four screens in the case of four color processprinting, with different color separation angles or with a differentmesh woven fabric, or both, merely compounds this expense to a printer.

The conventional manner of manufacturing a silk-screen for use in theprinting of halftones involves a number of individual steps. The firststep is to make color separations of the halftone image involved. Thisis done at a predetermined line count, preferably at a line count of 120lines of dots of color per inch, as such gives some latitude in thechoice of a woven fabric for use in making a silk-screen. The colorseparations may be made by either the printer or the manufacturer of thesilk-screens; however, it is generally made by the printer. Where thecolor separations are made by the printer, the silk-screen manufacturernevertheless confirms the halftone line count for each of the colorseparations made.

In general, the confirmation of line count involves the placement ofeach color separation or film positive, in turn, on a light table havinga single point incandescent light, e.g., a 60 watt bulb. On placing afilm positive on the light table, the crop marks provided in the filmpositive, at 3, 6, 9 and 12 o'clock, are lined up, in usual manner, withthose provided on the light table. Then, the film positive is taped inplace, emulsion, side up. A conventional halftone calculator is thenrotated in usual manner on top of each of the color separations. Thelargest moire effect visually observed indicates the line (or dot)count. This process is repeated for each of the colors involved.

Next, using a conventional Star Guide Orientator, the halftone angle forthe lines of dots of color for each color separation is determined. Thisis done, in general, by rotating the Star Guide on top of a filmpositive until the moire effect is again obvious. This indicates theangle of color separation for that particular color. The same lightsource is used for the color separation angle determination, as for theline count. In general, as earlier mentioned, the preferred angles forcolor separation are cyan (75°), black (45°), magenta (15°), and yellow(90° or 0°).

Next, one determines the proper thread count for the halftonesilk-screen printing to be done, i.e., the thread count of the wovenfabric to be used in the manufacture of a silk-screen whereby the effectof moire will be eliminated, or at least reduced. This is done byreference to a conventional chart showing the relationship betweenhalftone line count and the thread count of a woven fabric and moire. Ingeneral, the higher the thread count, the least likely that moire willresult, even over a relatively large range of halftone line count. Forexample, at a thread count of 465 threads/inch, there is littlepossibility that moire will result even at a halftone line count varyingfrom 85 lines/inch to 133 lines/inch. At a line count of 120 lines/inch,there is little likelihood of moire occurring at a mesh count of either420 or 465 mesh/inch. Having determined the line count for the colorseparations, one then chooses that mesh woven fabric for manufacture ofsilk-screens least likely to result in moire.

The next step is to determine the angle of mesh for each of the colorseparations at which moire can be least detected by visual observation.This is done, in general, by laying a 90° screen, i.e. the warp and weftthreads are at 90° relative to the rectangular-shaped frame of thescreen, of the right mesh size over the taped positive on the lighttable. The screen is then rotated by hand until moire can no longer bedetected, or at least until moire is localized and minimized. Therotation of the screen for moire to be no longer detected or to belocalized or minimized may need be done in some cases in a clockwisedirection, and in other cases in a counterclockwise direction. Aconventional protractor is then used to measure the angle, i.e., theangle of mesh, that a "moire free" screen varies from the startingposition, and in which direction. This procedure is followed for each ofthe colors involved.

A suitable size woven fabric, square cut, and of the thread countpreviously determined, is then located in conventional stretchingapparatus and stretched according to usual techniques. In general, thisis accomplished by grabbing each of the four edges of the fabric with anelongated stretching bar, i.e., the warp threads terminating in, forexample, opposed end edges are stretched in opposite directions, and theweft or fill threads terminating in opposed side edges are stretched inopposite directions. The screen fabric should be stretched to a tensionof at least about 16-18 newtons, an even higher tension being moredesirable. Importantly, however, all the screens to be used in, e.g. afour color printing process, must be at a consistent tension.

Once the woven fabric is stretched to the extent desired, silk-screenframes corresponding in number to the desired color separations made areplaced in contact with the bottom surface of the stretched fabric. Eachframe is then oriented in usual manner on the stretched fabric at thedesired angle, i.e., the angle at which it was previously determined, asabove disclosed, that moire could no longer be detected. Thisorientation is accomplished, in general, by means of a conventionalprotractor placed along an edge of the frame. Adhesive commonly used in,the manufacture of silk-screens is then applied to the top surface ofthe stretched fabric, after which it seeps downwardly through the meshof the woven fabric to the top surface of the screen frame. Thestretched fabric is thus adhered to the silk-screen frame. This processis repeated for each of the colors involved in the color separation.

The screens are then each provided with the halftone image to be printedby that screen. This is done, in general, by first applying aphotosensitive emulsion to the screen. A film positive, e.g., of thecolor separation of cyan, is then placed against the emulsion and theemulsion is exposed, for example, by ultraviolet light. The unexposedareas of the emulsion are then washed out in conventional manner. Thisprocedure is repeated for each of the color separations. The screens arethen ready to be used in a silk-screen printing operation.

Thus, it can be seen that the conventional manner in which silk-screensare manufactured involves a considerable number of steps. Moreover, thedetermination of the angles for the mesh of the woven fabric relative tothe screen frame to be used in the manufacture of a set of silk-screensfor halftone printing, as earlier described, and rotating of the chosenwoven fabric or film positives until it appears to the human eye thatmoire is eliminated, or at least more localized, is largely a hit andmiss proposition. The same is true with respect to the rotation of ascreen frame to be adhered to the stretched woven fabric. As will beappreciated, these procedures depend to a large extent upon the eyes ofthe person aligning the film positives or woven fabric relative to oneanother, and the accuracy of the placement of the protractor. The carryover of that angle to the placement and orientation of screen frames onthe stretched fabric using a protractor further compounds the problem.

More recently, a much improved process for the manufacture ofsilk-screens for use in the printing of halftones has been discovered,such a process being disclosed in U.S. Ser. No. 08/419,038, filed onApr. 10, 1995 and assigned to Autoroll Machine Corporation, the same asis this application. The disclosure of that patent application is fullyincorporated herein by reference. In general, in the process ofsilk-screen manufacture disclosed, the angle at which the mesh of awoven fabric should be, relative to the screen frame, whereby toeliminate or at least minimize or localize moire is predetermined foreach of the color film separations, using an off-line registrationapparatus, as disclosed in that patent application. This apparatus isprovided with an annular-shaped rotatable member on which the 90° screenframe is mounted. The apparatus is further provided with an indexingscale whereby the angle to which the screen is rotated at which moire iseliminated or minimized and localized is readily determined. Thus, thisoff-line registration apparatus eliminates the inherent potentialinaccuracies of using a protractor, as earlier disclosed.

The angle for each of the screens at which moire is eliminated or atleast minimized or localized is then carried to stretching apparatus forthe woven fabric to be used in the manufacture of the silk-screens. Thestretching apparatus is provided with a horizontally disposed tablelocated below the woven fabric in which is provided a plurality ofannular-shaped rotatable members each of which is provided with anindexing mark or member which mates with a scale. A silk-screen frame ismounted on a rotatable member for each of the colors involved, e.g. infour color process printing, four frames and rotatable members areinvolved. Subsequent to the mounting of a screen frame on a rotatablemember, the rotatable member is then rotated to the desired angle, aspreviously determined in the off-line registration process, for thatparticular color separation. Thus, the screen frame is oriented toprovide the frame at the right angle relative to the mesh of the wovenfabric to manufacture a silk-screen whereby moire is eliminated or atleast minimized or localized in the silk-screen printing process. Thewoven fabric is then stretched to the desired tension and the table israised so as to provide the top surface of each of the screen frames incontact with the woven fabric. The fabric is then adhesively secured toa screen frame in usual manner. The mesh in the woven fabric is thusprovided at the correct angle of color separation for each of the colorsinvolved. The stretched fabric is then cut at the outer perimeter ofeach of the screen frames providing silk-screens ready for furtherprocessing to provide them for use in a silk-screen printing operation.

Although this last mentioned manner of manufacture of silk-screens foruse in the printing of halftones is a substantial improvement over theconventional method used theretofore, as earlier disclosed, its use is,nevertheless, attendant with certain disadvantages. One disadvantageresults from the fact that screen frames used in this manner ofmanufacture of silk-screens are of a square or rectangular shape. Thus,as the screen frames need be necessarily spaced apart from one anotherto a certain extent to provide for the annular-shaped rotatable memberson the table, only a limited number of silk-screens can be manufacturedfrom any given size woven fabric. Another disadvantage in the manner ofmanufacture of silk-screens as disclosed in U.S. Ser. No. 08/419,038 isthat the angle at which the screen frames each need be oriented relativeto the stretched fabric must first be determined, and then the screenframes must each then be oriented at that angle relative to the mesh ofthe stretched fabric by rotation of the rotatable member on which thescreen frame is mounted on the table in the stretching apparatus.

Thus, it is highly desirable that an improved method for the providingof a set of silk-screens for use in the multicolor silk-screen printingof halftones, whereby moire can be eliminated, or at least localized andminimized, be provided. Further, it is desired to provide an even moresimplified method of providing silk-screens for use in the printing ofhalftones on compact discs.

SUMMARY OF THE INVENTION

The present invention has as a primary object the providing of a set ofsilk-screens for use in the multicolor silk-screen printing of halftoneson a flat surface not attendant with the problems and disadvantages inthe manufacture of such silk-screens heretofore.

Another object of the invention is to provide a novel silk-screen memberthat functions like a silk-screen and can be used in the printing ofhalftones.

A further object of the invention is to provide a silk-screen member foruse in the printing of halftones that can be located directly in theconventional printhead of a silk-screen printing apparatus during setup.

A further object of the invention is to provide a silk-screen memberwhich comprises the combination of a silk-screen and a carrier thereforwherein the mesh of the silk-screen are provided at the desired angle ofcolor separation.

A further object of the invention is to provide apparatus to be used inthe manufacture of silk-screens for use in the silk-screen member of theinvention whereby such apparatus results in an improved method for themanufacture of silk-screens to be used in halftone printing.

A still further object of the invention is to provide improved means fordetermining the angle at which the mesh in a woven fabric screen need beprovided in a silk-screen printing operation whereby moire is eliminatedor at least minimized and localized.

A still further object of the invention is to provide a more simplifiedmethod for determining the angle that the mesh must be provided toeliminate or at least minimize and localize moire in the silk-screenprinting of halftones.

A still further object of the invention is to provide a more simplifiedmethod for providing the mesh in a silk-screen at the correct angle toeliminate or at least minimize and localize moire in the silk-screenprinting of halftones.

An even further object of the invention is to provide a method ofproviding the mesh in the woven, stretched fabric in a silk-screen atthe angle at which moire is eliminated or at least minimized andlocalized in halftone printing that is determined off-line and apartfrom the stretching operation.

A still further object of the invention is to provide an improved methodfor the manufacture of a set of silk-screen members to be used inhalftone printing whereby moire is at least minimized or localized.

Quite advantageously, the providing of silk-screens according to theinvention makes good utilization of the stretched fabric from which thescreens are made. Moreover, the silk-screens provided according to theinvention allows every screen made to be used for any color separationangle desired.

Other objects and advantages will become apparent from the disclosurewhich follows hereinafter.

BRIEF DESCRIPTION OF THE DRAWING

For a better understanding of the present invention and its preferredembodiments, reference should be made to the following detaileddescription which is to be read in conjunction with the accompanyingdrawings, in which:

FIG. 1 is an exploded view in perspective of a silk-screen memberaccording to the invention comprising in combination a silk-screencomprising a circular-shaped screen of woven fabric (the woven fabricnot being shown in the drawing for sake of clarity) and anannular-shaped silk-screen frame, and a square-shaped carrier for thesilk-screen, the silk-screen member being ready for installation intothe nest of a printhead of a silk-screen printing machine;

FIG. 2 is a top plan view of stretching apparatus according to theinvention for the stretching of woven fabric used in the manufacture ofcircular-shaped silk-screens of the invention but without a woven fabricbeing shown so that the horizontally disposed table on which theannular-shaped screen frames are placed for manufacture of thecircular-shaped silk-screens can more readily be seen;

FIG. 3 is a cross-sectional view of the stretching apparatus shown inFIG. 2 taken at secant lines 3--3 and showing the fabric located inopposed stretching means;

FIG. 3A is an exploded view of the cross-section shown in FIG. 3, tobetter shown the relative locations of the woven fabric to be stretched,the annular-shaped screen frames, and the support member for the screenframes;

FIG. 4 is a moire detection device used in the practice of the inventionfor determining the angle that the mesh in the woven fabric of acircular-shaped silk-screen must be provided relative to the linear sideedges of a silk-screen carrier to eliminate or at least minimize andlocalize moire, and

FIG. 5 is an exploded view in perspective showing a silk-screencomprising a circular-shaped woven mesh screen (not shown) adhered to anannular-shaped screen frame in a carrier for use in the determination ofthe angle at which moire can be eliminated or at least minimized orlocalized.

DETAILED DESCRIPTION OF THE INVENTION AND THE PREFERRED EMBODIMENTSTHEREOF

While the present invention will be described hereinafter withparticular reference to the accompanying drawings, it is to beunderstood at the outset that it is contemplated that the presentinvention may be varied in specific detail from that illustrated anddescribed herein while still achieving the desirable characteristics andfeatures of the present invention, Accordingly, the description whichfollows is intended to be understood as a broad enabling disclosuredirected to persons skilled in the applicable arts and is not to beunderstood as being restrictive.

Turning now to FIG. 1 of the drawing there is shown therein asilk-screen member 10 according to the invention comprising thecombination of a circular-shaped silk-screen 12 and a carrier 14 for thesilk-screen. The silk-screen 12 comprises an annular-shaped silk-screenframe or ring member 16 defined by inner and outer diameters and by topand bottom 20 planar surfaces 18, 20, to the top surface 18 (the bottomsurface as shown in FIG. 1 ) of which is adhesively secured a stretchedwoven fabric (not shown) according to conventional techniques,hereinafter more fully disclosed. The stretched woven fabric is of acircular shape and of the same diameter as the outer diameter of theannular-shaped screen frame 16. On the bottom surface 220 of the screenframe 16 there are provided indexing marks or dots 22, 24, the purposefor which will later be made clear. These indexing marks can be otherthan dots, if desired. For example, linear marks can be inscribed in thesurface of the frame, such marks lying on a diameter of theannular-shaped frame. Or the indexing marks provided on the screen framecan take the form of dimples provided in the frame, or circular-shapedopenings provided therein. Nevertheless, whatever the form of theindexing marks, the important thing is that such be in opposition to oneanother and lie on a diameter of the annular-shaped screen frame. Indexmarks, as will be better appreciated later on, need also be provided onthe top surface of the screen frame, these being in direct opposition tothe index marks 22, 24.

The carrier 14 shown in FIG. 1 is of a square shape; however, it can beof 10 other shapes, if desired. For example, in some cases, the carrier14 may be of rectangular shape. The shape of the carrier will dependsomewhat upon the configuration of the nest of the print head in whichthe silk-screen member is to be placed. The carrier 14 is defined bylinear side edges 26, 28 and linear front and back end edges 30, 32 andby top and bottom planar surfaces 34, 36. The carrier 14 is furtherdefined by a circular-shaped opening 38 which defines a peripheral edge.The circular-shaped opening 38, as will be appreciated from FIG. 1, isof a diameter only slightly larger than the outer diameter of theannular-shaped screen frame 16. Thus, the screen frame will fit into thecircular-shaped opening 38, and be capable of being rotated therein.

Extending inwardly from the peripheral edge of the circular-shapedopening 38, are tabs 40, 42 defined by horizontally disposed planar topsurfaces 44, 46. The tabs prevent the silk-screen frame 16 from fallingthrough the circular-shaped opening 38 and, importantly, provide thewoven mesh screen in the same plane as that defined by the bottomsurface 36 of the carrier 14. Thus, it will be appreciated by thoseskilled in the art that the horizontally disposed surfaces 44, 46 of thetabs lie in a plane parallel to and somewhat lower than the planedefined by the top planar surface 18 of the carrier screen frame 12. Asshown in FIG. 1, the tabs 40, 42 are located at about 10 and 2 o'clock,respectively, considering that the opening 38 defines thecircular-shaped face of a clock, and 6 o'clock is closest to the viewer.On the top surface 34 of the carrier, there is provided a stop member48, the purpose for which will soon be made clear. Stop member 48 is ofrectangular shape and is fixedly secured to the carrier along the endedge 32. The length and width of the stop member can vary somewhat, asdesired. As will be seen from FIG. 1, the stop member is of a width toprovide an overlapping of the screen frame when such is located in thecarrier. Also, the stop member is so located that half of its length ison one side of 12 o'clock, and the other half of the length is on theother side of 12 o'clock. The important thing, however, is that suchmember, in combination with the tabs 40, 42, maintain the silk-screen 12in horizontal disposition, and provide the bottom surface 20 of thescreen frame in the same horizontal plane as that defined by the topsurface 34 of the carrier, and the plane of the woven fabric screen inthat plane defined by the bottom surface 36 of the carrier.

Although not shown in the drawing, it will be appreciated by thoseskilled in the art that four tabs can be provided, if desired, In suchevent, these other two tabs will be desirably located at about 8 and 4o'clock. Further, it will be recognized by those skilled in the art thatstop member 48 need not necessarily be of rectangular shape. The stopmember can be, for example, of arcuate shape, if desired, the straightedge of which is provided along the end edge 32. The main considerationis that such a member overlap the bottom surface of the annular-shapedscreen frame so as to maintain the screen frame in horizontaldisposition.

Of critical importance in the providing of a silk-screen member 10,according to the invention, the carrier 14 must be provided with meansto lock the silk-screen frame 12 in position so that the mesh in thewoven fabric screen are maintained at the angle determined earlier, aslater fully disclosed, to prevent moire in the silk-screen printing of asubstrate, e.g., the top surface of a compact disc. Such locking meanscan take various forms; however, the locking means 50, 52 shown in FIG.1 will be found quite suitable for the intended purpose. The lockingmeans 50, 52 are identical in construction and only one will be morefully described. Locking means 50 comprises, in combination, a latchmember 54, in which is provided an opening 56, an externally threadedmember 58, and an internally threaded member 60. The externally threadedmember 58 extends perpendicularly upwardly from the top surface 34 ofthe carrier. In operation, the bottom portion of the internally threadedmember 60 extends through the opening 56 and is screwed onto theexternally threaded member 58. The top portion of the member 60 is of alarger diameter than that of the opening 56 thereby allowing the latchmember to be securely fastened against the top surface of the carrierand the bottom surface 20 of the screen frame 12. It will be appreciatedthat the locking means disclosed is like that conventionally used tofasten storm door windows to the storm door frame. Also, those skilledin the art will readily appreciate that the member 60 can be externallythreaded at its bottom end and an internally threaded bore provided inthe carrier 14. Other locking means will also be found satisfactoryprovided they perform the intended function disclosed.

The carrier 14 is provided with openings 62, 64, as is shown in FIG. 1,these openings being spaced apart from one another to the same extentand of the same size and shape as are the openings provided in a square-or rectangular-shaped silk-screen frame conventionally used in asilk-screen printing apparatus. Thus, to this extent, carrier 14functions like a conventional silk-screen frame. As a result of this,the silk-screen member 10 can be, quite advantageously, directly placedinto the nest of the silk-screen printing head according to usualtechniques during setup of the silk-screen printing apparatus for aparticular run.

As will be readily appreciated by those skilled in the art ofsilk-screen printing, the dimensions of the carrier 14 will bedetermined by the printing head being used. The inner diameter of theannular-shaped screen frame 16 will be varied accordingly, the mainconsideration being that, in any case, the inner diameter of the screenframe must be such as to allow the flood bar to make a complete pass.

Turning now to FIGS. 2 and 3, there is shown therein stretchingapparatus 66 of largely conventional design, except for the base member68 and the horizontally disposed planar support member 70, both of whichwill soon be more fully described. In general, the stretching apparatus66 used in the practice of the invention comprises a bottom or basemember 68 of a box-like configuration defined by a horizontally disposedclosed bottom end 72 and spaced-apart, vertically upright, parallel endwalls, only one of which, end wall 74, is shown in the drawing, andparallel side walls 76, 78, these walls intersecting at 90 degreeangles, respectively, to one another. Thus, there is provided aninternal cavity of cubic shape, the purpose for which cavity will belater made clear.

Attached to the top end of the base member 68 and providing a closuretherefor is a horizontally disposed member or platform 80 which lies ina plane parallel to that of the bottom end 72. The member 80 is definedby planar top and bottom surfaces 82, 84. As will be seen from thedrawing, the member 80 is defined by extensions 86, 88, 90, and 92, thetop surfaces of which are in the same horizontal plane as the topsurface 82 of the top closure member 80. The extensions 86, 88, 90, and92 each support clamping means designated generally by referencenumerals 94, 96, 98, and 100, respectively. The clamping means eachcomprises a plurality of conventional Tetko pneumatic clamps or clampingmembers, identified in general by reference numeral 102. These clampingmembers are available commercially from TETKO INC. of Briarcliff, N.Y.under the trade designation #SST Clamp.

As the clamping members 102 are of identical construction, only one willbe further described herein. In general, the clamping members, as bestseen in FIG. 3, each comprise a head 104 and a clamp base 106, the clampbase 106 being defined by a horizontally disposed flat surface which issupported on the top surface of an extension. The head 104 of a clampingmember is provided, at its front end, with a locking clamp 108 wherebythe warp and weft edges of the unstretched fabric 110 to be stretchedcan be securely gripped. The locking clamp 108 is movable toward andaway from engagement with the fabric holding member 112 whereby theedges of the fabric can be gripped securely for stretching and thenreleased, when desired.

Each clamping member head 104 comprises a piston (not shown) providedwith a connecting piston rod 114 the free end of which extends throughan opening in a piston rod support member 116 which extends upwardlyfrom the outer end of the clamp base 106. The piston rod in each of theclamping member heads is fixedly secured in the respective piston rodsupport member 116 thereby allowing the head 104 of a clamping member tobe moved in a back and forth direction. Thus, the clamping members inopposition to one another can be caused to move toward and away from oneanother, as desired. Although not shown in the drawings, those clampingmembers in opposition to one another, e.g., the clamping members 102provided in the clamping means 94 and those in clamping means 98, areconnected to conventional pressure means whereby an equal amount ofpressure can be supplied to each of the clamping members.

The clamping members, in and of themselves, and their operation andlocation in the stretching apparatus, need not be further described, itis believed, as such forms no part of the invention disclosed herein.Other clamping means can be used in the practice of the invention. Theonly thing of importance is that the clamping means for stretching thewoven fabric be arranged in a square pattern, as the woven fabric beingstretched is of a square shape, i.e., the warp and weft threads of thewoven fabric terminate in ends that define spaced-apart parallel linearside and end edges that intersect with one another at 90 degree angles.Thus, the ends of the warp and weft threads that define these side andend edges are engaged by the clamping members.

To prepare a woven fabric 110 for stretching, in general, the ends ofthe warp and weft threads of the fabric 110 are provided on the holdingmembers 112 of the respective clamping members 102. Then, an operatorengages a clamp handle 118 and, by hand, raises it upwardly and pushesit forward whereby to clamp securely, onto the thread ends located onthe holding member. This is done for each of the clamping memberswhereby the edges of the fabric are securely engaged. Next, pressure isapplied to the clamping member pistons whereby to cause the head ofopposed clamping members 102 to move away from one another therebyproviding the desired amount of tension on the fabric. The clamping base106 of each of the clamping members 102 in a clamping means, e.g., thoseclamping members 102 in clamping means 94 (FIG. 2), are held to the topsurface of an extension by an elongated bridging member or slat 120. Aswill be readily appreciated from FIG. 2, a slat 120 is mounted to asupport member extension whereby to be in perpendicular disposition tothe lengthwise direction of a clamp base 106. The front edge of a slat120 is located against a shoulder or stop member 122 provided on the topsurface of a clamp base 106 (FIG. 3). Although not shown in the drawingsfor sake of clarity, and because the clamping members are commerciallyavailable and are not a part of the invention in and of themselves, aclamp head 104 rides in a track which causes a clamp head to maintain alinear back and forth movement. The backward movement of a clamp head issuch that it is limited to the back edge of a slat 120. Each clamp base106 is provided at its front end with a vertically disposed stop member124, the purpose for which is primarily for safety reasons. Thus, in theevent there should be a failure in pressure, the clamp members will beprevented from going forward beyond this point.

Although, it is common practice that the same pressure be applied to allthe clamping member pistons, that need not necessarily be the case. Thepressure supplied to the stretching apparatus 66 can be different foropposing stretching means. For example, a predetermined pressure can besupplied to those opposed clamping members in clamping means 94, 98 anda lesser or greater predetermined pressure applied to those opposedclamping members in clamping means 96, 100. Accordingly, it is mostpreferred in the practice of the invention that pressure be appliedindependently to the opposed clamping means. The means for doing suchcan be readily accomplished by those skilled in the art. Thus, in theevent that such is desired, different tensions can be applied to thewarp and weft threads.

It makes no difference, however, in setting up the stretching apparatus66 for the stretching of the fabric 110 which of the clamping meansclamps which edges, i.e., the ends of the warp threads or the ends ofthe weft threads. The important consideration is that the fabric besquare to the square shape defined by the clamping means.

Although, as shown in FIG. 2 of the drawing, the clamping means eachcomprises five (5) clamping members, this is not necessarily critical inthe practice of the invention. The clamping means may each include agreater or lesser number of clamping members. This will depend somewhatupon the size fabric involved and the width of the clamping memberchosen. In the practice of the invention, with a plain weave fabric sizeof 61"×61", 5 clamps (10" wide clamps) will be found to give quitesatisfactory results in the stretching of the woven fabric. As willreadily be appreciated by those skilled in the art, and as earlierdisclosed, other stretching means comprising other clamping members mayalso be used in the practice of the invention, provided they accomplishthe function intended herein.

Located below the fabric 110 and between the fabric and the top surface82 of the platform or member 80 (FIG. 3), and this is a critical featureof the invention, there is provided a horizontally disposed table orsupport member 70 defined by top and bottom planar surfaces 126, 128(FIG. 3). The support member 70 is disposed horizontally so that the topplanar surface 126 of the support member is provided parallel to thehorizontally disposed plane defined by the stretched fabric 110. Thesupport member 70 is mounted according to conventional techniques (notshown) so as to be movable vertically upwardly and downwardly, towardand away from the bottom surface of the fabric 110, the reason for whichsoon be made clear. This can be accomplished by various means known tothose skilled in the art, e.g. crank operated hydraulic lifts or bypneumatic means, as desired. In general, four hydraulic lifts will beprovided for raising and lowering of the support member, and these willbe provided in such locations as to better ensure that the supportmember 70, in its raised position, is provided in a horizontal plane andparallel to that plane defined by the stretched fabric 110.

As will be seen from FIG. 2 of the drawing, a plurality of spaced-apartindex marks, referred to generally by reference numeral 130, areprovided on the top surface 126 of the horizontally disposed table 70,in predetermined spaced-apart locations. These index marks, as shown inthe drawing, are located on a straight line extending between, andperpendicular to, the parallel side edges 132, 134 of the table 70.Although not shown in the drawing, a row of spaced-apart index marks 130will be provided on the surface of the table for each of the rows ofannular-shaped screen frames 16 provided on the table, In this case, itwill be seen that four rows of screen frames are provided, each rowcomprising four screen frames, arranged in vertical columns therebyproviding a square pattern of screen frames, Next adjacent index marksin a row, e.g. index marks 130 and 130', should be spaced-apart adistance a little greater than the outside diameter of theannular-shaped screen frame, the reason for this soon being made clear,if not already obvious. The index marks 130 can take various forms, e.g.dimples in the table surface, painted dots provided on the surface, +marks, etc., provided they accomplish the intended purpose, as latermore fully disclosed. It will be appreciated by those skilled in the artthat index marks can be provided on the table surface in both horizontalrows and vertical columns, if desired. In this case, the index means forlocation of the annular-shaped screen frames can, if desired, beintersecting lines that extend between the side edges and end edges ofthe table. Although not shown in the drawing, indexing marks can, ifdesired, be provided at the linear side edges of the table 70, or at thelinear end edges, or on both the side and end edges.

The table 70 is further defined by a plurality of openings indicatedgenerally by reference numeral 136, these providing communication withthe internal cavity defined by the side and end walls of the base member68 by means of funnel-like members denoted generally by referencenumeral 137. The bottom of the funnel-like members extend throughopenings provided in the top closure of the base member. Although notshown in the drawing, as such forms no part of the invention disclosedherein, conventional vacuum means are connected to the internal cavitywhereby to rid the cavity of toxic fumes as later disclosed.

The manufacture of the circular-shaped silk-screens of the invention isaccomplished by first placing a plurality of annular-shaped screenframes 16 on the top surface 126 of the table 70. These annular-shapedscreen frames, as will be seen by reference to FIG. 2, are arranged in aplurality of horizontal rows and vertical columns of screen frames, fourscreen frames being provided in each column and row shown in thedrawing. The screen frames are arranged in a square pattern, a screenframe having both a row and column address. The annular-shaped screenframes 16 are provided in close proximity to one another, the peripheraledge defined by the outer diameter of a screen frame being almost intangential contact with the peripheral edge of a next adjacentannular-shaped screen frame. In locating the screen frames on the table70, and this is critical to the practice of the invention, the opposedindex marks 22, 24 of a screen frame will be aligned with opposed, nextadjacent index marks 130, 130' provided on the table. This can beaccomplished by visually lining up the index marks.

Although not earlier disclosed, and not shown in FIG. 2, the index marksprovided on the annular-shaped screen frame and those provided on thetable 70 supporting the screen frames can take the form ofcircular-shaped openings. The openings provided in the table 70 as indexmeans should be spaced apart the same distance as the index marksprovided in the screen frame, In this case, the openings in the screenframe can be aligned with adjacent and corresponding openings providedin the table and a pin-like member can be then inserted into the alignedopenings. Thus, quite advantageously, the screen frames can bemaintained in the properly registered locations on the table untiladhered to the stretched fabric, as later disclosed. As will beappreciated by those skilled in the art, the head of such a member mustbe located below the plane defined by the top surface 18 of the screenframe. One can readily accomplish this by providing that the openings inthe screen frame be provided with a thread pattern. Then, an elongatedthreaded member having a thread pattern on a part of its length can bescrewed into the two openings in the screen frame, making sure that thetop of the elongated member is below the top surface of the screenframe. The bottom ends of the elongated pin-like members, which are freeof threads can be located in the openings provided in the table. Whenthe screens are removed from the stretching table, as later disclosed,the threaded pin members can then be removed from the bottom side of thescreen. This can be faciliated by providing a groove in the bottom endof the pin-like member, like that provided in the head, whereby a screwdriver can be used to remove the pin-like member from the screen frame.

Of advantage in the practice of the invention disclosed herein, it willbe seen that with the same size stretching apparatus and woven fabric(61"×61") used in the manufacture of silk-screens, according to themethod disclosed in U.S. Pat. No. 5,562,030, earlier disclosed, the useof an annular-shaped screen frame, rather than a square-shaped frame,allows a greater number of silk-screens to be made at any one time. Ofeven greater advantage, however, the use of annular-shaped screen framesin the manufacture of silk-screens, allows such a silk-screen to be usedin any angle desired in a silk-screen printing process. This will becomemore clear later.

The stretching apparatus 66 used in the practice of the invention, asearlier disclosed, is preferably provided with means (not shown) forindependently or simultaneously controlling the tension provided on thewarp and weft threads. Thus, referring to FIG. 2 of the drawing, thedistance between the opposing clamping means 94, 98 is made greater orless, if desired, than that between the clamping means 96, 100, toprovide the tension desired on the warp or weft threads of the wovenfabric 110, as the case may be. The means for accomplishing such afunction can be readily provided by one skilled in the art. For example,pneumatic means (not shown) can be provided to control the separationbetween opposed clamping means, hence the tension on the warp and weftthreads.

Once the screen frames 16 are properly located and aligned on the table70, a woven fabric 110 (e.g, a plain weave 465 mesh count woven fabric)is cut into a 61" square and the warp and weft edges thereof placed onthe surfaces of the fabric holding members 112 of the clamp members 102.This fabric can be cut before the screen frames are located on thesupport member, if desired. The particular sequence is of no particularimportance.

The fabric used in the manufacture of silk-screens is typically apolyester fabric as such has good elongation characteristics whichallows the woven mesh fabric to achieve higher tensions, and with ashorter stretch time than with other fabrics. Importantly, the fabricedges are provided square with the lengthwise directions of the clampingmeans, i.e., the clamping means 94, 98 clamp on the ends of the warpthreads of the woven fabric and the clamping means 96, 100 clamp on theopposed ends of the weft threads. It will be appreciated by thoseskilled in the art, however, that the reverse can be done, if desired.The critical concern is that the ends of the warp and weft threads besubstantially square with the square shape defined by the four clampingmeans of the stretching apparatus. This will, of course, provide thatthe stretching of the fabric be substantially at 90 degrees. The clampmembers 102 in each of the clamping means should desirably beindividually operable to allow for adjusting the linearity of the meshto assure as approximate a 90 degree stretch of the woven fabric aspossible.

With any adjustments made as deemed necessary, the warp and weft threadsof the woven fabric 110 are ready to be brought to the desired tension,in usual manner. The tensions on the warp and weft threads are increasedby increasing the distance between opposed clamping means. Desirably,the tension on the warp and weft threads will be the same. The fabric isgenerally stretched in two stages. The first stretch should be such asto provide a tension that is slightly more than half (measured innewtons) the final tension desired. The tension at any particular pointin the stretching operation can be determined in usual fashion using aconventional tension meter gauge measuring in newtons.

Using a low elongation polyester fabric (e.g. a plain weave fabric, 46520 mesh) the final stretch should achieve a tension of about 24 newtonswith a relaxed stretch of about 20 newtons. Thus, in the first stage,the woven fabric is brought to a tension of about 12 newtons, afterwhich it is allowed to relax according to usual techniques. As is wellknown to those skilled in the art, this relaxation period is essentialin stretching any fabric comprising polymeric strands due to themolecular structure of the particular polymeric material involved.Otherwise, the fiber strands making up the woven fabric may snap. Therelaxation time desired in any particular case depends, at least inpart, upon two variables. One is the particular fabric provided bydifferent manufacturers. The other is how uniform the stretching is inbringing the warp and weft threads to the desired tension. Therelaxation time in any particular case is determined empirically throughtest stretching, in advance. Following relaxation of the woven fabric,after having been stretched in the first stage, the fabric is thenstretched to full tension. At full tension, the tension at the fourcorners and in the center of the stretched fabric is checked. This isdone to determine whether the overall tension is the same across theentire fabric surface. The tension on both the warp and weft threads inthese locations is determined. The tension readings should desirablyfall within + or -1 newton to assure that all screen frames will becompatible when imaged. In any event, those skilled in the art know thatto obtain close registration in the silk-screen printing of multiplecolors, for example, four color process printing, it is important thatany variation in tension across the stretched fabric from which screensare manufactured be kept as low as possible. Where tension is differentacross the stretched fabric, the result will be silk-screens from thatsame fabric with different tensions, causing the images on eachsilk-screen to be stretched differently from one another. Thus, the lessthe variation in tension, the closer the registration that can beobtained in the printing process.

When the woven polyester fabric has been stretched to the desiredtension, the top surfaces 18 of the annular-shaped screen frames 16provided on the horizontally disposed support member 70 are then placedin contact with the stretched fabric. This is accomplished by causingthe support member 70 to be raised vertically upwardly until the topsurfaces of the screen frames 216 are each slightly pressed against thebottom surface of the stretched woven fabric 110. The screen framesshould, of course, be of a rigid material, e.g., steel frames, It isimportant, of course, that the screen frames 16 used be planar withoutany bowing therein and that the frames each be seated on the supportmember 70 to lie flat against the top surface 126 of the support member.Otherwise, the stretched fabric may not be properly adhered to theannular-shaped screen frames.

At this time, adhesive is applied in usual manner to that portion ofstretched fabric in opposition to the top surface 18 of anannular-shaped screen frame 16. Thus, a small bead of cyanoacrylateadhesive is typically applied to the stretched fabric such penetratingthrough the woven fabric strands by capillary action and the mesh of thefabric to the top surface of the screen frame contacting the bottomsurface of the stretched fabric. The adhesive can be, if desired,troweled so as to ensure penetration through the meshes in the fabricand to provide a layer of adhesive on the surface of the screen frame,The accelerator for the cyanoacrylate adhesive is then sprayed onto thestretched woven fabric according to usual techniques whereby theadhesive is cured to provide a tight bond between the stretched wovenfabric and the surface of the screen frame. Each frame is secured in thesame manner to the stretched woven fabric. Those skilled in the art willappreciate that other adhesives may be used instead of a cyanoacrylateadhesive, if desired. Further, the means of application may also differ,for example, a layer of adhesive can be applied directly to the screenframe prior to the screen frame being placed in contact with thestretched fabric. Nevertheless, the adhesive used and manner ofapplication earlier disclosed will be found to produce quitesatisfactory results and is preferred in the practice of the invention.

The toxic fumes from the adhesive bonding operation, as earlierdisclosed are caused to be drawn into the internal cavity of the basemember 68. Thus, as will be appreciated by those skilled in the art,this is caused by the vacuum communicating with the internal cavityprovided in the base member and the openings 136 provided in the supportmember 70. The openings 136 can individually communicate with the cavityin the base member or the openings can communicate with a manifoldmember that, in turn, communicates with the cavity in the base member.Those skilled in the art can readily provide either construction, asdesired.

Quite advantageously, as the height of the support member 70 isadjustable, this allows for the woven fabric 110 to be stretched to thedesired tension, out of contact with the annular-shaped screen frames16. Then, the support member 70, with the screen frames located thereon,and properly registered as desired, is raised to provide contact betweenthe stretched woven fabric, i.e. the screen, and the top surface 18 ofthe screen frame 16. Thus, the screen frame is adhesively secured to thebottom surface of the stretched woven fabric. The screen frames eachhaving been provided on the support member 70 in the desiredorientation, i.e., with the index marks 22, 24 on the screen frames inalignment, and forming a straight line from one linear side edge of thesupport member to the other, will result in the warp or weft threads ofthe fabric, as the case may be, being in parallel alignment with thediameter of the annular-shaped screen frame on which the index marks 22,24 lie. Although the screen frames have been disclosed earlier to beprovided with only two index marks, four index marks can be provided oneach screen frame, if desired. Thus, considering the annular-shapedscreen frame as being the face of a clock, index marks can be providedat 3, 6, 9, and 12 o'clock. With four index marks, each screen frame canbe oriented with respect to both the warp and weft threads of the wovenfabric. In this case, index marks will be provided on the support member70, in both horizontal rows and in vertical columns.

Once the adhesive has been cured, and the stretched fabric 110 has beenadhesively secured to each of the annular-shaped screen frames, thetension on the stretched fabric is then released. The circular-shapedsilk-screens 12 are then each removed from the excess fabric by cuttingthe fabric along the outer peripheral edges of each of theannular-shaped screen frames 16. Thus, the manufacture of thecircular-shaped silk-screens is complete. Each of the circular-shapedsilk-screens made is like the others, i.e., the warp and weft threads,hence the mesh of the woven fabric is aligned in the same mannerrelative to the index marks 22, 24 provided on a screen frame. Thesilk-screens 12 are each then ready to be used in the determination ofthe angle at which moire can be eliminated or at least minimized andlocalized in the silk-screen printing of a particular color of thehalftone image of concern, as disclosed hereinafter. Of great advantage,the making of circular-shaped screens, according to the invention,rather than ones of a square or rectangular shape, permits the use ofthe screens at any angle needed for the elimination of, or at least theminimization or localization of moire. Further, the processabove-disclosed allows the making of four sets of silk-screens at onetime to be used in four color process printing. Thus, there is not onlybetter utilization of woven fabric but a savings in cost of labor andmaterial.

Referring now to FIG. 4 of the drawing, there is shown therein moiredetection apparatus 138 which provides means for the determination ofthe angle at which the mesh in a circular-shaped silk-screen 12, earlierdisclosed, i.e., the mesh of the stretched woven fabric in thecircular-shaped silk-screen, must be located in the silk-screeningprinting of a halftone image to eliminate or at least minimize orlocalize moire. Quite advantageously, contrary to the manner ofmanufacture of silk-screens heretofore, this angle is determined, andthe mesh of the screen are provided at the proper angle in a separateand distinct operation from that of manufacturing the silk screens.Accordingly, this greatly simplifies this determination.

The angle at which moire can be detected and then eliminated or at leastminimized or localized depends largely upon the halftone colorseparations made and the resulting film positives, as will be later morefully disclosed. The color separations to be made in any particular casewill, of course, depend upon the colors in the particular image orartwork to be duplicated, e.g., the artwork, image or information to besilk-screen printed on, e.g., a compact disc (not shown) according tousual techniques.

The moire detection apparatus 138 comprises a body member 140 ofbox-like construction defined by vertically upright, spaced-apart sidewalls 142, 144, parallel to one another and upright, spaced-apart endwalls 146, 148, as seen from the drawing. The body member 140 is closedat its bottom end in usual manner by a horizontally disposed planar,bottom member 150 providing means for support of the moire detectionapparatus on a horizontally disposed surface such as a table (notshown). Nevertheless, if desired, the moire detection apparatus can beintegral with the top surface of a cabinet which is provided with asuitable number of drawers for storage of masks, as disclosed later on,color separation film positives, etc.

The top end of the body member 140 is provided with a top closure 152which preferably, as seen in FIG. 4, tapers downwardly from the back endwall 148 to the front end wall 146. This feature, quite advantageously,allows one to best view a color film positive and moire relationship, aswill be later made more fully clear. Nevertheless, the top closure canbe in a plane parallel to that defined by the bottom member of the bodymember 140, if desired; however, that is less preferred. In the topclosure 152, there is provided a centrally located, circular-shapedopening 154 in which is located a plate glass window 156 fixedly securedto the peripheral edge 158 defining the opening. This plate glass windowprovides means for the centering location of color separation filmpositives, as later disclosed. The diameter of the circular-shapedopening can vary somewhat; however, an opening 5.25" is most preferred,as such a size opening will be found useful in centering the filmpositives. Although not shown in FIG. 4, there is located behind theplate glass window an incandescent light providing a single source oflight behind the centrally located, circular-shaped opening. Aconventional 60 watt bulb will be found quite satisfactory for thepurposes of this invention. Thus, the body member 140 functionsessentially as a light box for the viewing of the color film positives,as later disclosed.

As will be seen from FIG. 4, two vertically disposed, spaced-apartregistration pins 160, 162 are provided on the top closure 152, thepurpose for which will soon be made clear. It is of critical importancethat these two registration pins be of the same size and in the samespaced-apart location as the registration pins conventionally providedon the mounting bracket for a silk-screen of a silk-screen printingapparatus with which the circular-shaped silk-screens are to be used. Aswill be appreciated by those skilled in the art of silk-screen printing,the size and location of these registration pins can vary somewhat andwill be determined by the screen registration system of the silk-screenprinting apparatus in which the circular-shaped silk-screens and screenmember 10 are to be used.

The first step in the providing of a silk-screen member 10 according tothe present invention, if such has not been done already by thesilk-screen printer, is to make the halftone color separations, e.g.,make positive films of each of the colors to be printed, i.e., cyan,black, magenta, and yellow of the halftone image to be reproduced on,for example, a compact disc. This is done by techniques well known tothose skilled in the silk-screen printing art, the preferred separationbeing at approximately 120 lines of dots of color per inch.

If the color separations have already been made, e.g., by the printerwho is going to be doing the silk-screen printing of, e.g., compactdiscs, the line count is, nevertheless, confirmed. The reason for thisis that an accurate line count is critical to the determination of theangle of the mesh in the silk-screen at which moire can be eliminated orat least minimized or localized, as disclosed hereinafter. Thisconfirmation can be accomplished in conventional manner by using acommercially available halftone calculator. To do this, the colorseparations or film positives, provided by the printer are each, inturn, affixed to a light box having a single point incandescent lightsource (60 watt bulb), and the halftone line count made by the printeroperator is confirmed. The line count for the color separation ofconcern is confirmed, in general, by noting where the greatest effect ofmoire occurs. The moire detection apparatus 138 can be, quiteadvantageously, used for this purpose. In the event the printer operatorhas not provided the color separations, such will be made by thesilk-screen manufacturer according to conventional techniques.

Nevertheless, regardless of who made the color separations from thehalftone image to be printed, it is most preferable that half-toneseparations having a line count of 120 be made. With a line count of 120lines/inch, as well known to those skilled in the printing art, thereexists the least possibility for moire to occur using a woven fabrichaving a mesh count of either 420 or 465 lines/inch. Even with fabrichaving a mesh count of 355 or 380, any moire is usually localized. Thisinformation is readily available from a conventional mesh/dot and moirerelationship chart.

Having confirmed, or made as the case may be, the line count for each ofthe color separations or the color separations themselves, the fourcolor process film positives obtained from the color separations, in thecase of four color process printing, are then each employed, in turn, inthe moire detection apparatus, as hereinafter disclosed. This is todetermine the angle at which the mesh of the woven fabric, i.e.,silk-screen, need be provided in the silk-screen printing process toeliminate, or at least minimize or localize moire in the silk-screenprinting of the particular halftone image. Thus, one of the four colorprocess film positives (not shown) is placed on the plate glass window156 located in the opening 154 of the top closure 152 with the emulsionside up. Crop or registration marks provided on the color film positive,e.g., at 3, 6, 9, and 12 o'clock, in usual fashion, are aligned withlike crop marks provided on the top closure (not shown in the drawing)to provide the color film positive in square disposition with the sidewalls of the body member 140 and centered over the opening 154. Thecolor film positive so located is then taped in place.

A silk-screen carrier 164 of planar configuration, as shown in FIG. 5,is then mounted to the moire detection apparatus 138. The carrier 164 isdefined by side edges 166, 168, in parallel disposition to one anotherand by parallel end edges 170, 172 which intersect at 90° with the sideedges. The carrier 164 is further defined by a circular-shaped opening174, the diameter of which is only slightly greater than the outerdiameter of the annular-shaped screen frame 16. The circular-shapedopening 174 defines a circular-shaped peripheral edge along a portion ofwhich is provided a scale 176, as shown in FIG. 5. The scale isconveniently divided into one degree marks (1°-180°) and is locatedadjacent the bottom end edge 170. Nevertheless, it will be understood,if desired, that the scale can be located adjacent the top end edge 172,or for that matter that the scale can be a full 360 degrees.

Importantly, there are provided in the carrier 164, two openings 178,180, these being spaced apart from one another to the some extent as thepins 160, 162 provided on the top closure of the body member 140 (FIG.4). Thus, when the carrier 164 is placed on the top closure, the carrierwill be provided in square disposition with the body member of the moiredetection apparatus, the linear side edges 166, 168 of the carrier beingin parallel disposition to the parallel side walls 142, 144 of the bodymember 140. The carrier 164 can be mounted to the body member 140 priorto placing the color film positive (not shown in the drawing) on theplate glass window, if desired. Nevertheless, this is less preferred asit proves somewhat more difficult to place the color film positive inthe proper registration and to tape it in place.

Next, one of the circular-shaped screens 12, manufactured as earlierdisclosed, is located in the carrier 164, being placed on top of thecolor film positive, with the mesh side down. Quite advantageously, anyone of the screens 12 made, as earlier disclosed, can be used in thisdetermination. The diameter of the circular-shaped opening 174 in thecarrier is only slightly greater than the outer diameter of theannular-shaped screen frame 12. Thus, the screen frame will be freelyrotatable relative to the periphery of the opening 174. Importantly, thelocation of the circular-shaped opening in the carrier and the locationof the registration pins 160, 162 provide the circular-shaped screen(not shown in the drawing) concentric to the opening 154 in the topclosure 152. Thus, the color film positive will be centrally locatedwith respect to the screen. It will be recalled that either the warp orweft threads of the woven fabric screen are in parallel disposition tothe index marks 22, 24. Thus, in placing the silk-screen 12 in thecarrier 164, the screen frame is first rotated so that the lines of meshin the screen defined by the warp and weft threads, and this is acritical feature of the invention, are first aligned to be square withthe linear side edges 166, 168 of the carrier 164. Thus, with respect tothe carrier shown in FIG. 5, the index mark 22 will be located at the90° mark on the scale. Although the scale shown in FIG. 5 is from 0° at9 o'clock to 180° at 3 o'clock, it will be appreciated by those skilledin the art that the scale may read from the opposite direction, ifdesired. Alternatively, if desired, the scale can read 0° at 6 o'clockand from 0° to 90° to 3 and 9 o'clock, respectively.

Next, the circular-shaped silk-screen 12 is then rotated by hand slowlyin the carrier opening 174 in a clockwise direction to determine at whatangle moire is eliminated or at least reduced or localized for thatparticular color separation. The rotation of the screen frame can befacilitated, if desired, by providing a threaded opening (not shown) inthe top surface of the screen frame. A threaded handle or protuberancecan then be located in the threaded opening to aid the rotation of thescreen frame and then subsequently removed, when desired. Focus, duringrotation of the silk-screen frame, should be maintained upon a smallpart of the visual field provided by the opening 154 in the top closureof the body member 140 whereby moire can be more readily detected by thehuman eye. If one focuses on the image seen in the entire visual field,it is somewhat difficult, at times, to interpret the moire pattern as itchanges with rotation of the silk-screen. It will be appreciated thatthe silk-screen 12 rotates independently of the color film positivewhich is in a fixed location on the top closure 152.

As the circular-shaped silk-screen 12 is rotated, moire is seen to beeliminated or at least becomes minimal or undetectable by the human eyefor that particular color separation. Once this point is reached, anindex mark is provided on the screen frame at 6 o'clock, i.e, at the 90°index mark on the carrier scale. This mark can take various forms, onebeing a pressure-sensitive adhesive tape in the form of an arrow, Thus,the angle determined by the index mark 22 and the arrow mark is theangle that the mesh lines in the stretched woven fabric in thesilk-screen should be provided, relative to the linear side edges of thecarrier to eliminate or at least minimize or localize moire. If desired,the silk-screen 12 can be locked in place in the carrier 164 by lockingmeans provided on the carrier. The locking means can be like thatearlier disclosed for carrier 14, or different, as desired.Alternatively, the angle that index mark 22 on the silk-screen framemakes with the scale 176 provided on the carrier can be read. Thedifference between this angle and the angle of the index mark 22initially (FIG. 5) is then determined. It will be appreciated by thoseskilled in the art that this angle is the same as that determined by thearrow marker placed at 6 o'clock. In this case, a scale will need beprovided also on the carrier 14 (FIG. 1 ). Whatever the manner of"remembering" the angle at which moire is eliminated or at leastminimized or localized, it is important that this angle be retained forlater use. The carrier 164 and silk-screen 12 are then removed from themoire detection apparatus 138 and the woven fabric silk-screen isprovided with photosensitive emulsion according to usual techniques.

The other color film positives are then each, in turn, in like manner asearlier described, placed on the plate glass window 156, taped down, acarrier 164 is located in place, and a silk-screen 12 placed in thecarrier. The silk-screens in each instance are rotated and the angle atwhich moire is eliminated or at least minimized or reduced for each ofthe color film positives is determined in a manner as earlier disclosed.Thus, the angle at which moire is at least minimal or localized for eachof the silk-screens to be used in the particular half-tone printingprocess is determined. The circular-shaped silk-screens, while stilllocked in place in their respective carriers 164 at the angle at whichmoire has been eliminated or at least minimized or localized for thatparticular color separation, are then each coated with a photosensitiveemulsion in conventional manner. Although mechanical locking means canbe used for locking the screen frame in place relative to the carrier,in some cases, the index marker provided at 6 o'clock, as earlierdisclosed, can be used as both a marker and locking means. For example,a length of pressure-sensitive adhesive tape having a straight edge canbe used to mark the 6 o'clock location on the screen frame, such tapebeing of sufficient length to extend onto and be attached to the topsurface of the carrier 164.

Meanwhile, while the silk-screens 12 are each being coated with thephotosensitive emulsion, the four color film positives, in the case offour color process printing, are registered relative to one another. Theregistration of the color film positives to one another is facilitatedby use of a carrier mask (not shown in the drawings) of planarconfiguration and defined by a frame of square shape. To this carriermask there is detachably secured a clear 7 mil MYLAR polyester filmmeasuring the same size as the frame. Such a film thickness is desirableas it will provide stability to the film and the film will not shrink onbeing heated. The polyester film is provided at its bottom edge with twoopenings, these corresponding in location to two openings provided inthe frame of the carrier mask. The frame openings, as are those in thepolyester film, are of a diameter and so located as to fit onto theregistration pins 160, 162 provided on the top closure of the bodymember 140 of the moire detection apparatus 138, as earlier disclosed.In the center of the carrier mask film, there is provided a 51/4circular-shaped opening, the purpose for which will soon be made clear,It will be appreciated by those skilled in the art that this opening isof the same diameter as the plate glass window 156 provided in theopening 154 in the top closure of the body member, and concentrictherewith.

Although not earlier disclosed, it will be seen by reference to FIG. 4,that a plurality of small openings 182 are provided around theperipheral edge 158 of the opening 154. These openings 182 communicatewith the internal cavity provided in the body member 140 defined by thevertically disposed end and side edges and the top and bottom closures.Also communicating with the cavity is a conventional vacuum pump (notshown), the purpose for which will soon be clear.

One of the film positives, having previously been provided with crop orregistration marks in usual manner at 90 degrees to one another, e.g.,at 3, 6, 9, and 12 o'clock, is placed at 90 degrees to the plate glass156, i.e., square to the body member, emulsion side down. The color filmpositive is held in place by vacuum. Next, one of the carrier masks islocated on the registration pins 160, 162, This carrier mask is taped tothe underlying color film positive. The second color film positive ispositioned on top of the first carrier mask placed down and the secondcolor film positive is visually aligned with the first color filmpositive. The second color film positive is then lightly taped, i.e., soit can later be detached from the first color film positive and carriermask therefor, to the first color film positive and first carrier mask.The second carrier mask is then placed on the registration pins 160,162. Thus, it is positioned over the second color film positive and inregistration with the first carrier mask. The second carrier mask isthen taped to the second color film positive. The third color filmpositive is then placed on top of the second carrier mask and this colorfilm positive is visually aligned to the first and second color filmpositives and taped lightly in position to the second color filmpositive and second carrier mask. This process of alignment andattachment of color film positives to carrier masks continues until eachof the color film positives is provided in registration with the others,each color film positive being taped to a respective carrier mask and acolor film positive being lightly taped to the color film positive belowit and to its carrier. Thus, there is provided a "sandwich" comprising,in the case of four color process printing, four alternating color filmpositives and four carrier masks, the color film positives being inregistration one with the other. The sandwich is then taken apart sothat a single color film positive is associated with a single carriermask. This can readily be done as the alternating color film positivesare only lightly taped to an underlying color film positive and carriermask.

The sequence in which the color film positives are provided inregistration with one another is of no particular significance. It isimportant, however, that the central portion of the color film positivebe so located as to show through the opening provided in the carriermask. As the openings in the carrier masks are each centrally locatedand coincide with the circular-shaped plate glass 156 and opening 154 inthe top closure 152 of the body member 140, the central portion of eachof the color film positives will be superimposed one above the other andin a coinciding relationship.

Thus, in the case of four color process printing, a set of four colorprocess film positives are provided. Each member of the set can then beused in providing an image on a circular-shaped silk-screen, as earlierdisclosed, and according to usual technique. Each carrier mask from theset (with a color film positive taped thereto) is then provided with apin member or metal tab in each of the openings provide in the carriermask, as earlier disclosed. Such a tab has an elongated pin havingessentially the same diameter as the opening in a carrier mask, butbeing insertable therein, and a flat holding member, the plane of whichextends perpendicular to the length of the pin.

The pinned carrier masks are each then provided in combination with arespective carrier 164 in which is located a circular-shaped screen 12previously provided with a coating of photosensitive emulsion. This isaccomplished by locating the pin member of the pinned carrier mask inthe holes provided in the silk-screen carrier, as earlier disclosed. Itis, of course, of critical importance that the mesh of thecircular-shaped screen located in that carrier has been oriented in theproper angle relative to the linear side edges of the carrier for theelimination or at least the localization or minimizing of moire in thesilk-screen printing of that particular color. The emulsion on thesilk-screens is then exposed to light and the carrier mask is removedfrom the carrier. The unexposed areas of the emulsion are then washedaway in conventional manner. The silk-screens are then ready to be usedin the silk-screen printing of the artwork or information involved.

Importantly, the silk-screens 12 with the exposed photosensitiveemulsions thereon are then each removed from the moire detectioncarriers, i.e. carriers 164, and are placed in nesting screen carriers,i.e., screen carriers 14. These two carriers are of similarconfiguration; however, there are also important differences, as canreadily be seen from FIGS. 1 and 5. The screen carrier 14, instead ofbeing provided with a scale, as is screen carrier 164, is merelyprovided with an index mark 182, this mark being located at 6 o'clock,as shown in the drawing. Furthermore, the screen carrier 14 is providedwith cut-outs, as indicated by reference numeral 184. Cut-outs of adifferent configuration, may need be provided to accommodate theconfiguration of the particular print head nest (not shown) but wellknown to those skilled in the art of silk-screen printing. Inanticipation of making a printing run, the silk-screens 12 are locatedin the openings 38 of the carriers 12, the one end of the screen frame16 being located below the stop member 48. The bottom surface of thescreen frame will rest upon the top surface of the tabs 40, 42 and besupported thereby. Although not shown in the drawing additional tabs canbe provided to support the screen frame, if desired.

Of critical importance, the screen frame in either of the carriers mustbe freely rotatable whereby to determine, and then provide the mesh ofthe woven fabric screen at, the desired angle to eliminate or at leastminimize or localize moire. The angle of the mesh in carrier 14,relative to its side edges must be the same as the angle of the meshrelative to the side edges of carrier 164, determined, as earlierdisclosed, in the moire detection device 138. Thus, the arrow index markprovided on the screen frame at 6 o'clock in the moire detection processmust be aligned with the index mark 182, provided at 6 o'clock in thecarrier 14. Thus, the mesh in the silk-screens will each be located atthe correct angle to eliminate or at least minimize or localize moire inthe artwork or graphics silk-screen printed on the printed object.

Quite advantageously, with the color film positives each being taped toa carrying mask and at the correct angle for registration of the filmpositives with one another, silk-screens can readily be re-imaged, asand when desired, Those skilled in the art will be appreciative of thefact that the films should each be attached to a carrying mask by apermanent transparent tape, to assure no movement or shrinkage of thetape while the carrier mask and attached color film positive are beingstored for possible later use.

As will be understood by those skilled in the art, various modificationsand changes can be made in the invention and its form and constructionwithout departing from the spirit and scope thereof. The embodiments ofthe invention disclosed herein are merely exemplary of the variousmodifications that the invention can take and the preferred practicethereof. It is not, however, desired to confine the invention to theexact construction and features shown and desired herein, but it isdesired to include all such as properly come within the spirit and scopeof the invention disclosed and claimed.

We claim:
 1. Method for providing the mesh of a silk-screen comprising astretched woven fabric defined by a plurality of warp and weft threadsfor use in the silk-screen printing of a halftone image on a flatsurface at the correct angle for the elimination or minimization orlocalization of moire comprising the following steps:(a) providing asilk-screen comprising an annular-shaped screen frame defined by top andbottom planar surfaces and by predetermined inner and outer diameters,first and second indexing means being provided on the top and bottomsurfaces of the screen frame, said indexing means being provided on saidtop and bottom planar surfaces in opposition to one another and on thesame diameter of the annular-shaped screen frame and a circular-shapedwoven mesh fabric comprising a plurality of warp and weft threadsattached to said annular-shaped screen frame; (b) providing a carrierfor the silk-screen, said carrier being of planar configuration definedby top and bottom surfaces and by spaced-apart, parallel top and bottomlinear end edges and spaced-apart, parallel linear side edgesintersecting with the linear end edges at 90 degree angles, acircular-shaped opening of predetermined diameter being provided in thecarrier, said circular-shaped opening defining a circular-shapedperipheral edge and being located centrally between the linear end andside edges, the diameter of the circular-shaped opening being onlyslightly larger than the outer diameter of the annular-shapedsilk-screen frame whereby the silk-screen frame is located in thecircular-shaped opening of the carrier, and being freely rotatabletherein, said circular-shaped opening defining a clock face andproviding a predetermined location at 6 o'clock, and a scale beingprovided along the peripheral edge of the circular-shaped opening; (c)placing the silk-screen in the carrier, said silk-screen being solocated that one of said first and second indexing means on said screenframe is located opposite from the 6 o'clock location on the screencarrier and the warp and weft threads of said circular-shaped woven meshfabric are provided in parallel disposition to one of said linear sideand end edges, respectively, of the circular-shaped woven mesh fabric;(d) providing a light source for the viewing of a color process filmpositive taken from a halftone image to be silk-screen printed; (e)placing said color process film positive emulsion side up in oppositionto the light source; (f) placing the carrier with the silk-screenlocated therein and facing downwardly over said color process filmpositive; (g) visualizing the color process film positive through thesilk-screen while rotating the annular-shaped screen frame in thecarrier until moire is eliminated or at least minimized or localized inthe color process process film positive; (h) placing indexing means onthe screen frame opposite said 6 o'clock location on the carrier wherebyto determine the angle at which the mesh of the woven fabric screen isto be located relative to the linear side edges of the carrier toeliminate or at least minimize or localize moire in the printingoperation.
 2. Method according to claim 1 wherein two openings areprovided in the carrier adjacent the bottom linear end edge, said twoopenings being spaced apart from one another a distance and provided inlike locations as are the openings in a screen frame placed in a nest ofa silk-screen printing machine.
 3. Method according to claim 2 whereinthe light source provided comprises a box-like body member, a topclosure defined by top and bottom surfaces being provided on the bodymember, a circular-shaped opening being provided in the top closure, anda light source being provided in said body member opposite thecircular-shaped opening below the bottom surface of the top closure. 4.Method according to claim 3 wherein two spaced-apart vertically uprightregistration pins are provided on the top surface of the top closure ofthe body member, said registration pins being located a distance apartas to intrude into the openings provided in the carrier.
 5. Method forproviding the mesh of a stretched woven mesh fabric in a silk-screen atan angle for the minimization or localization of moire in a silk-screenprinting process comprising the following steps:(a) providing halftonecolor separations of an image to be silkscreen printed to provide acolor process film positive for each of the colors of said image to beprinted, an emulsion side defining said color process film positive; (b)providing a silk-screen comprising an annular-shaped screen frame ofpredetermined inner and outer diameters, a top and bottom planar surfacebeing provided on said annular-shaped screen frame, indexing means beingprovided on said annular-shaped screen frame, and a stretched woven meshfabric comprising a plurality of warp and weft threads being adhesivelysecured to the top planar surface of said annular-shaped screen frame;(c) providing a carrier for the silk-screen, a top and bottom planarsurface being provided on said carrier, and said carrier being definedby spaced-apart, parallel front and back linear end edges andspaced-apart, parallel linear side edges intersecting with the linearend edges at 90 degree angles, a circular-shaped opening ofpredetermined diameter being provided in the carrier, saidcircular-shaped opening defining a circular-shaped peripheral edge andbeing located centrally between the linear end and side edges, thediameter of the circular-shaped opening being only slightly larger thanthe outer diameter of the annular-shaped silk-screen frame whereby theannular-shaped silk-screen frame is freely rotatable therein, saidcircular-shaped opening defining a clock face and providing apredetermined location at 6 o'clock on the front end of the carrier, anda scale being provided along said circular-shaped peripheral edge of thecircular-shaped opening; (d) placing the silk-screen in said carrier insuch a fashion that said top planar surface of said annular-shapedscreen frame faces downwardly, said annular-shaped silk-screen being solocated that said indexing means on said annular-shaped screen frame islocated opposite from the 6 o'clock location on the screen carrier and awarp and weft thread of the stretched woven mesh fabric is provided inparallel disposition to one of said linear side and end edges,respectively; (e) providing a light source for viewing said colorprocess film positive; (f) placing said color process film positiveemulsion side up opposite said light source and in a predetermined fixedlocation; (g) placing the carrier with the silk-screen located thereinand said top planar surface of said annular-shaped screen frame facingdownwardly over said color process film positive; (h) rotating saidsilk-screen relative to said fixed location of said color process filmpositive; (i) visualizing the color process film positive through thestretched woven mesh fabric of said silk-screen while rotating theannular-shaped screen frame until moire is at least minimized orlocalized in the color process film positive; and (j) placing anindexing means on the annular-shaped screen frame opposite said 6o'clock location on the carrier whereby to determine the angle at whichthe mesh of the woven mesh fabric in the silk-screen is to be locatedrelative to the linear side edges of the carrier to at least minimize orlocalize moire in a silk-screen printing process.
 6. Method according toclaim 5 further comprising reading the angle on said scale at which theindexing means placed on the annular-shaped screen frame after beingrotated is located opposite said 6 o'clock location provided on theperipheral edge of said circular-shaped opening in said carrier anddetermining the difference between the angle read and the angle of theannular-shaped screen frame when said indexing means provided on saidannular-shaped screen frame is opposite from the 6 o'clock location onthe screen carrier before being rotated.
 7. Method according to claim 6wherein two spaced apart openings are provided in the carrier adjacentthe front linear end edge, said two spaced apart openings being spacedapart from one another a distance and provided in a predeterminedlocation, as are the spaced-apart openings in a non-circular screenframe placed in a nest of a silk-screen printing machine.
 8. Methodaccording to claim 7 wherein the light source provided comprises abox-like body member, a top closure being provided on said box-like bodymember comprising a top and bottom surface, a circular-shaped openingbeing provided in said top closure, and a light source is providedopposite the circular-shaped opening and below the bottom surface of thetop closure.
 9. Method according to claim 8 wherein two spaced-apartvertically upright registration pins are provided on the top surface ofthe top closure of the body member, said registration pins being solocated and spaced apart as to intrude into the openings provided in thecarrier.
 10. Method for providing the mesh of a stretched woven meshfabric in a silk-screen to be used in a multicolor process silk-screenprinting process at an angle for the minimization or localization ofmoire comprising the following steps:(a) providing halftone colorseparations of an image to be silkscreen printed on a surface to providea color process film positive for each of the colors of said image to beprinted, an emulsion side defining said color process film positive; (b)providing a silk-screen comprising an annular-shaped screen frame ofpredetermined inner and outer diameters, a top and bottom planar surfacebeing provided on said annular-shaped screen frame, indexing means beingprovided on at least the bottom surface of said annular-shaped screenframe, and a stretched woven mesh fabric comprising a plurality of warpand weft threads being adhesively secured to the top planar surface ofsaid annular-shaped screen frame; (c) providing a carrier for thesilk-screen, a top and bottom planar surface being provided on saidcarrier, and said carrier being defined by spaced-apart, parallel frontand back linear end edges and spaced-apart, parallel linear side edgesintersecting with the linear end edges, a circular-shaped opening ofpredetermined diameter being provided in the carrier, saidcircular-shaped opening defining a circular-shaped peripheral edge andbeing located centrally between the linear end and side edges, thediameter of the circular-shaped opening being only slightly larger thanthe outer diameter of the annular-shaped silk-screen frame whereby theannular-shaped silk-screen frame is freely rotatable in saidcircular-shaped opening, a clock face being defined by saidcircular-shaped opening and providing a fixed location at 6 o'clock onthe front end of the carrier, and a scale being provided along saidcircular-shaped peripheral edge of the circular-shaped opening, a pairof openings being provided in said carrier along the front edge; (d)placing the silk-screen in said carrier in such a fashion that said topplanar surface of said annular-shaped screen frame faces downwardly; (e)rotating said screen frame to provide said indexing means on saidannular-shaped screen frame opposite from the 6 o'clock location on thescreen carrier and to align a warp and weft thread of the stretchedwoven mesh fabric in parallel disposition to one of said linear side andend edges, respectively; (f) providing a moire detection apparatus ofbox-like configuration, vertically upright side and end walls definingsaid box-like configuration and an internal cavity being provided insaid box-like configuration, a top closure defined by a top surface anda bottom surface being provided in said box-like configuration, acentrally located circular-shaped opening being provided in said topclosure, a glass window being provided in said circular-shaped opening,a light source for viewing said color process film positive of thehalftone image to be silk-screen printed being provided in said cavitybelow said bottom surface and in opposition to said glass window, a pairof spaced apart registration pins being provided on said top closure,said registration pins being spaced apart the same distance as theopenings provided in said carrier and a line connecting saidregistration pins being in perpendicular disposition to said side wallsof the moire detection apparatus; (g) placing said color process filmpositive emulsion side up on said glass window and in fixed oppositionto said light source, crop marks being provided on said color processfilm positive whereby to provide said color process film positive insquare relationship to the side walls of said moire detection apparatus;(h) placing the carrier with the silk-screen located therein and saidtop planar surface of said annular-shaped screen frame facing downwardlyover said color process film positive and locating said registrationpins of the moire detection apparatus in the openings of said moiredetection apparatus in the openings of said carrier whereby said carrieris provided in fixed relationship to said moire detection apparatus; (i)rotating said silk-screen in said carrier relative to said fixed colorprocess film positive and said fixed carrier; (j) visualizing the colorprocess film positive through the stretched woven mesh fabric of saidsilk-screen while rotating the annular-shaped screen frame until moireis at least minimized or localized in the color process film positive;and (k) placing a further indexing means on the top surface of theannular-shaped screen frame opposite said 6 o'clock location on thecarrier whereby to determine the angle at which the mesh of the wovenmesh fabric in the silk-screen is to be located relative to the linearside edges of the carrier to at least minimize or localize moire in asilk-screen printing process.
 11. Method for providing the mesh of astretched woven mesh fabric in a silk-screen to be used in a multicolorprocess silk-screen printing process at an angle for the minimization orlocalization of moire comprising the following steps:(a) providinghalftone color separations of an image to be silkscreen printed on asurface to provide a color process film positive for each of the colorsof said image to be printed, an emulsion side being provided on saidcolor process film positive; (b) providing a silk-screen comprising anannular-shaped screen frame of predetermined inner and outer diameters,a top and bottom planar surface being provided on said annular-shapedscreen frame, indexing means being provided on at least the bottomsurface of said annular-shaped screen frame, and a stretched woven meshfabric comprising a plurality of warp and weft threads being adhesivelysecured to the top planar surface of said annular-shaped screen frame;(c) providing a moire detection carrier for the silk-screen, a top andbottom planar surface being provided on said carrier, and said carrierbeing defined by spaced-apart, parallel front and back linear end edgesand spaced-apart, parallel linear side edges intersecting with thelinear end edges, a circular-shaped opening of predetermined diameterbeing provided in the carrier, said circular-shaped opening defining acircular-shaped peripheral edge and being located centrally between thelinear end and side edges, the diameter of the circular-shaped openingbeing only slightly larger than the outer diameter of the annular-shapedsilk-screen frame whereby the annular-shaped silk-screen frame is freelyrotatable in said circular-shaped opening, a clock face being defined bysaid circular-shaped opening and providing a fixed location at 6 o'clockon the front end of the carrier, and a scale being provided along saidcircular-shaped peripheral edge of the circular-shaped opening, a pairof openings being provided in said carrier along the front end edge; (d)placing the silk-screen in said moire detection carrier in such afashion that said top planar surface of said annular-shaped screen framefaces downwardly; (e) rotating said screen frame to provide saidindexing means on said annular-shaped screen frame opposite from the 6o'clock location on the moire detection carrier and to align a warp andweft thread of the stretched woven mesh fabric in parallel dispositionto one of said linear side and end edges, respectively; (f) providing amoire detection apparatus of box-like configuration, vertically uprightside and end walls defining said box-like configuration and an internalcavity being provided in said box-like configuration, a top closuredefined by a top surface and a bottom surface being provided in saidbox-like configuration, a centrally located circular-shaped openingbeing provided in said top closure, a glass window being provided insaid circular-shaped opening, a light source for viewing said colorprocess film positive of the halftone image to be silk-screen printedbeing provided in said cavity below said bottom surface and inopposition to said glass window, a pair of spaced-apart registrationpins being provided on said top closure, said registration pins beingspaced apart the same distance as the openings provided in said carrierand a line connecting said registration pins being in perpendiculardisposition to said side walls of the moire detection apparatus; (g)placing said color process film positive emulsion side up on said glasswindow and in fixed opposition to said light source, crop marks beingprovided on said color process film positive whereby to provided saidcolor process film positive in square relationship to the side walls ofsaid moire detection apparatus; (h) placing the moire detection carrierwith the silk-screen located therein and said top planar surface of saidannular-shaped screen frame facing downwardly over said color processfilm positive and locating said registration pins of the moire detectionapparatus in the openings of said carrier whereby said moire detectioncarrier is provided in fixed relationship to said moire detectionapparatus; (i) rotating said silk-screen in said moire detection carrierrelative to said fixed color process film positive and said fixed moiredetection carrier; (j) visualizing the color process film positivethrough the stretched woven mesh fabric of said silk-screen whilerotating the annular-shaped screen frame until moire is at leastminimized or localized in the color process film positive; (k) placing afurther indexing means on the top surface of the annular-shaped screenframe opposite said 6 o'clock location on the carrier whereby todetermine the angle at which the mesh of the woven mesh fabric in thesilk-screen is to be located relative to the linear side edges of thecarrier to at least minimize or localize moire in a silk-screen printingprocess; (l) providing a nesting screen carrier for said annular-shapedscreen frame, a circular-shaped opening being provided in said nestingscreen carrier of a diameter only slightly larger than the-outerdiameter of the annular-shaped screen frame whereby the screen frame isrotatable relative to the nesting screen carrier, a front edge beingprovided on said nesting screen carrier, an indexing means beingprovided on said front edge; (m) placing said annular-shaped screenframe into said nesting carrier; and (n) rotating the annular-shapedscreen frame in said nesting carrier to provide said further indexingmeans on the bottom surface of said annular-shaped screen frame inopposition to the indexing means provided on the nesting screen carrier.